Nucleotide sequence at the inverted terminal repetition of adenovirus type 2 DNA

Multiple domains in the 50 kDa form of E4F1 regulate promoter-specific repression and E1A trans-activation

The 50 kDa N-terminal product of the cellular transcription factor E4F1 (p50E4F1) mediates E1A289R trans-activation of the adenovirus E4 gene, and suppresses E1A-mediated transformation by sensitizing cells to cell death. This report shows that while both E1A289R and E1A243R stimulate p50E4F1 DNA binding activity, E1A289R trans-activation, as measured using GAL-p50E4F1 fusion proteins, involves a p50E4F1 transcription regulatory (TR) region that must be promoter-bound and is dependent upon E1A CR3, CR1 and N-terminal domains. Trans-activation is promoter-specific, as GAL-p50E4F1 did not stimulate commonly used artificial promoters and was strongly repressive when competing against GAL-VP16. p50E4F1 and E1A289R stably associate in vivo using the p50E4F1 TR region and E1A CR3, although their association in vitro is indirect and paradoxically disrupted by MAP kinase phosphorylation of E1A289R, which stimulates E4 trans-activation in vivo. Multiple cellular proteins, including TBP, bind the p50E4F1 TR region in vitro. The mechanistic implications for p50E4F1 function are discussed.

Nucleotide sequence of the S-2 mitochondrial DNA from the S cytoplasm of maize

Mitochondria from the S male-sterile cytoplasm (cms-S) of maize contain two plasmid-like DNAs, S-1 and S-2, that appear to be prominently involved with the cytoplasmic male sterility trait. The complete nucleotide sequence of the S-2 DNA molecule was determined by the chain termination method. The linear S-2 DNA molecule contains 5,452 base pairs and is terminated by exact 208-base-pair inverted repetitions. Two large open reading frames were identified in the S-2 DNA, suggesting the possibility of protein-encoding genes. The nucleotide sequence of the S-2 termini are discussed with regard to models proposed for the replication of linear DNA molecules.

Inhibition of adenovirus DNA synthesis in vitro by sera from patients with systemic lupus erythematosus

Sera containing antinuclear antibodies from patients with systemic lupus erythematosus (SLE) and related disorders were tested for their effect on the synthesis of adenovirus (Ad) DNA in an in vitro replication system. After being heated at 60 degrees C for 1 h, some sera from patients with SLE inhibited Ad DNA synthesis by 60 to 100%. Antibodies to double-stranded DNA were present in 15 of the 16 inhibitory sera, and inhibitory activity copurified with anti-double-stranded DNA in the immunoglobulin G fraction. These SLE sera did not inhibit the DNA polymerases alpha, beta, gamma and had no antibody to the 72,000-dalton DNA-binding protein necessary for Ad DNA synthesis. The presence of antibodies to single-stranded DNA and a variety of saline-extractable antigens (Sm, Ha, nRNP, and rRNP) did not correlate with SLE serum inhibitory activity. Methods previously developed for studying the individual steps in Ad DNA replication were used to determine the site of inhibition by the SLE sera that contained antibody to double-stranded DNA. Concentrations of the SLE inhibitor that decreased the elongation of Ad DNA by greater than 85% had no effect on either the initiation of Ad DNA synthesis or the polymerization of the first 26 deoxyribonucleotides.

Adenoviruses with nonidentical terminal sequences are viable

Adenovirus genomes consist of linear DNA molecules containing inverted terminal repeat sequences (ITRs) of 100 to 200 base pairs. The importance of identical termini for viability of adenoviruses was investigated. The viral strains used in this study were wild-type adenovirus type 5 (Ad5) and a variant Ad2 strain with termini which were distinct from those of all other human adenoviruses sequenced to date. A hybrid virus (sub54), obtained by recombination between Ad2 and Ad5, derived the left 42 to 52% of its genome from Ad2 and the right 58 to 48% from Ad5. Southern blotting analysis with labeled oligodeoxynucleotides indicated that both Ad2 and Ad5 ITRs were present in sub54 viral DNA preparations, and successive plaque purifications of sub54 demonstrated that viruses with nonidentical terminal sequences were viable but were rapidly converted to viruses with identical ends. Cloning of the sub54 genome as a bacterial plasmid supported the observations made by analysis of sub54 virion DNA. A plasmid, pFG154, was isolated which contained the entire adenovirus genome with an Ad2 ITR at the left terminus covalently linked to an Ad5 ITR at the right terminus. Upon transfection of mammalian cells with pFG154, viral progeny were obtained which had all possible combinations of termini, thus confirming that molecules with nonidentical termini are viable. Pure populations of viruses with nonidentical termini could not be isolated, suggesting efficient repair of one end with the opposite terminus used as a template. A model for this process is proposed involving strand displacement replication and emphasizing the importance of panhandle formation (annealing of terminal sequences) as a replicative intermediate.

Characterization of the simian adenovirus type 30 inverted terminal repeat

The presence of an inverted terminal repeat (ITR), which plays an important role in the initiation of DNA replication, is one of the characteristic properties of adenoviruses (Ads). We have established the nucleotide (nt) sequences for the ITR of simian adenovirus type 30 (SV30), a subgroup-III oncogenic virus. This repeat consists of 185 nt, representing the longest ITR found in an Ad so far. It contains multiple copies of internal repeats, as well as the consensus sequences of the putative binding sites for replication and transcription factors. The conserved features of the known ITRs are also found in SV30. Interestingly, the ITR of SV30 is more closely related to that of Ad5 (human), than to that of SA7 (simian).

Phylogenetic relationships between adenoviruses as inferred from nucleotide sequences of inverted terminal repeats

The nucleotide (nt) sequences of inverted terminal repeats (ITR) from human adenovirus (Ad) 19, bovine Ad1 (BAd1), bovine Ad3 (BAd3), canine Ad2 (CAd2) and an avian Ad, EDS-76, were determined. The length of the ITR sequence was 160 bp in Ad19, 159 bp in BAd1, 195 bp in BAd3, 196 bp in CAd2 and 52 bp in EDS-76. CAd2 had the longest ITR among the examined Ads, BAd3 the second longest, and EDS-76 had the shortest ITR. A TAAT sequence located between the 10th and 13th nt counted from the ends was conserved in all Ads examined so far. To determine phylogenetic relationships among human and animal Ads, sequences of their ITRs were compared, and a phylogenetic tree was constructed by using the maximum-likelihood method. It is the method involving statistical analysis of computing the probability of a particular set of sequences on a given tree and maximizing this probability over all evolutionary trees [Felsenstein, J. Mol. Evol. 17 (1981) 368-376]. From these analyses, it was found that members belonging to the same human Ad subgenus are related closely to each other, whereas representatives of different human subgenera are distributed rather divergently among animal Ads.

Deletion of cellular DNA at site of viral DNA insertion in the adenovirus type 12-induced mouse tumor CBA-12-1-T

The adenovirus type 12 (Ad12)-induced mouse tumor CBA-12-1-T contains greater than 30 copies of viral DNA integrated into cellular DNA. One of the sites of linkage between the left terminus of Ad12 DNA and mouse DNA was cloned, mapped and sequenced by using conventional techniques. The preinsertion sequence was also cloned from normal CBA/J mouse DNA and sequenced. The sequence data and blotting analyses demonstrated that at the site of linkage nine nucleotide pairs of viral DNA and at least 1500 to 1600 nucleotide pairs of cellular DNA were deleted. Up to the site of linkage, the cellular DNA sequence in CBA-12-1-T tumor DNA and the preinsertion sequence in CBA/J mouse cells were identical. The site of Ad12 DNA integration was found to be located close to a site of transition from unique to repetitive cellular DNA sequences. The nucleotide sequence at the site of linkage and at the preinsertion site revealed palindromic stretches of 5 and 10 nucleotides pairs, respectively. Scattered patch homologies (8-10 nucleotide pairs long) were observed between adenoviral and cellular DNAs. A hypothetical model for DNA arrangements at the site of recombination is presented.

Structure and function of the adenovirus origin of replication

Efficient initiation of adenovirus DNA replication requires the presence of specific terminal nucleotide sequences that collectively constitute the viral origin of replication. Using plasmids with deletions or base substitutions in a cloned segment of DNA derived from the terminus of the adenovirus 2 genome, we have demonstrated that the origin contains two functionally distinct regions. The first 18 bp of the viral genome are sufficient to support a limited degree of initiation. However, the presence of a sequence in the region between nucleotides 19 and 67 greatly enhances the efficiency of the initiation reaction. This region contains a specific binding site for a protein present in uninfected cells (KD = 2 X 10(-11) M). The bound protein protects the DNA segment between base pairs 19 and 43 from attack by DNAase I. Studies with deletion mutants indicate that binding of the cellular protein is responsible for the enhancement of initiation.

DNA sequences required for the in vitro replication of adenovirus DNA

Initiation of adenovirus (Ad) DNA replication occurs on viral DNA containing a 55-kilodalton (kDa) protein at the 5' terminus of each viral DNA strand and on plasmid DNAs containing the origin of Ad replication but lacking the 55-kDa terminal protein (TP). Initiation of replication proceeds via the synthesis of a covalent complex between an 80-kDa precursor to the TP (pTP) and the 5'-terminal deoxynucleotide, dCMP. Formation of the covalent pTP-dCMP initiation complex with Ad DNA as the template requires the viral-encoded pTP and DNA polymerase and, in the presence of the Ad DNA binding protein, is dependent upon a 47-kDa host protein, nuclear factor I. Initiation of replication with recombinant plasmid templates requires the aforementioned proteins and an additional host protein, factor pL. Deletion mutants of the Ad DNA replication origin contained within the 6.6-kilobase plasmid pLA1 were used to analyze the nucleotide sequences required for the formation and subsequent elongation of the pTP-dCMP initiation complex. The existence of two domains within the first 50 base pairs of the Ad genome, both of which are required for the efficient use of recombinant DNA molecules as templates in an in vitro DNA replication system, was demonstrated. The first domain, consisting of a 10-base-pair "core" sequence located at nucleotide positions 9-18, has been identified tentatively as a binding site for the pTP [ Rijinders , A. W. M., van Bergen, B. G. M., van der Vliet , P. C. & Sussenbach , J. S. (1983) Nucleic Acids Res. 11, 8777-8789]. The second domain, consisting of a 32-base-pair region spanning nucleotides 17-48, was shown to be essential for the binding of nuclear factor I.

Site-specific nicking within the adenovirus inverted terminal repetition

Site-specific nicking occurs on the l-strand, but not on the r-strand, of the adenovirus left inverted terminal repeat. Nicks are presumably introduced into double- or single-stranded DNA by a cellular endonuclease in an ATP-independent reaction. The consensus nick site has the sequence: (sequence in text).

Template requirements for the initiation of adenovirus DNA replication

The first step in the replication of the adenovirus genome is the covalent attachment of the 5'-terminal nucleotide, dCMP, to the virus-encoded terminal protein precursor (pTP). This reaction can be observed in vitro and has been previously shown to be dependent upon either viral DNA or linearized plasmid DNA containing viral terminal sequences. Plasmids containing deletions or point mutations within the viral terminal sequence were constructed by site-directed mutagenesis. In the case of linear double-stranded templates, pTP-dCMP formation required sequences located within the first 18 base pairs of the viral genome. This sequence contains a segment of 10 base pairs that is conserved in all human adenovirus serotypes. Point mutations within the conserved segment greatly reduced the efficiency of initiation, while a point mutation at a nonconserved position within the first 18 base pairs had little effect. Single-stranded DNAs can also support pTP-dCMP formation in vitro. In contrast to the results obtained with duplex templates, experiments with a variety of single-stranded templates, including phage M13-adenovirus recombinants, denatured plasmids, and synthetic oligodeoxynucleotides, failed to reveal any requirements for specific nucleotide sequences. With single-stranded templates containing no dG residues, the specific deoxynucleoside triphosphate requirements of the initiation reaction were altered.

Integration of viral DNA into the genome of the adenovirus type 2-transformed hamster cell line HE5 without loss or alteration of cellular nucleotides

Hamster cell line HE5 has been established from primary LSH hamster embryo cells by transformation with adenovirus type 2 (Ad2) (1). Each cell contains two to three copies of integrated Ad2 DNA (2, 3). We cloned and sequenced the sites of junction between viral and cellular DNAs. The terminal 10 and 8 nucleotides of Ad2 DNA were deleted at the left and right sites of junction, respectively. The integrated viral DNA had an internal deletion between map units 35 and 82 on the Ad2 genome. At the internal site of deletion, the remaining viral sequences were linked via a GT dinucleotide of unknown origin. From HE5 DNA, the unoccupied sequence corresponding to the site of insertion was also cloned and sequenced. Part of this sequence was shown to be expressed as cytoplasmic RNA in HE5 and primary LSH hamster embryo cells. The viral DNA had been inserted into cellular DNA without deletions, rearrangements or duplications of cellular nucleotides at the site of insertion. Thus, insertion of Ad2 DNA appeared to have been effected by a mechanism different from that of bacteriophage lambda in Escherichia coli and from that of retroviral genomes in vertebrates. It was conceivable that the terminal viral protein (4) was somehow involved in integration either on a linear or a circularized viral DNA molecule.

Initiation of adenovirus DNA replication in vitro requires a specific DNA sequence

Initiation of adenovirus DNA replication in vitro occurs on a linearized plasmid DNA containing 3,327 base pairs of the adenovirus terminal sequence. Various deletions have been constructed in the plasmid DNA and their template activities examined. Deletions from an internal restriction enzyme cleavage site that retain only 20 base pairs or more of the adenovirus terminal sequence support initiation and limited chain elongation, whereas deletions that leave 14 base pairs or less of the terminal sequence do not. On the other hand, all deletions extending from the very terminus of the adenovirus DNA destroy the template activity. The terminal 20 base pairs of adenovirus DNA contain a sequence A-T-A-A-T-A-T-A-C-C, which is perfectly conserved in the DNAs from different serotypes of human adenovirus. Base changes within the conserved sequence greatly reduce the template activity. These results suggest that the terminal 20 base pairs constitute a functional origin for the initiation of adenovirus DNA replication in vitro.

Specific binding of a cellular DNA replication protein to the origin of replication of adenovirus DNA

Nuclear factor I, a 47-kilodalton protein, purified from nuclear extracts of uninfected HeLa cells, is involved in the initiation and possibly the elongation of replicating adenovirus (Ad) DNA in vitro. The binding of nuclear factor I to DNA has been monitored by a filter binding assay of nuclear factor I to DNA has been monitored by a filter binding assay using plasmid pLA1 DNA, which contains a 3,290 base-pair fragment derived from the left-hand terminus (coordinates, 0-9.4 map units) of Ad serotype 5 DNA. Nuclear factor I binds selectively to a double-stranded fragment spanning nucleotides 0-451 to the Ad genome. The retention of the 451-base-pair DNA fragment-nuclear factor I complex on nitrocellulose filters does not require Mg2+ or ATP and is resistant to high ionic strength. DNase I protection experiments revealed that nuclear factor I binds to a nucleotide sequence located at position 17-48, close to the terminus of Ad DNA. This 32-nucleotide sequence contains four "consensus" sequences present in various serotypes of Ad DNA and is capable of forming higher ordered structures. The role of nuclear factor I and this DNA sequence in the generation of Ad preterminal protein-dCMP initiation complex is discussed.

Structure and reversion of an adenovirus type 2 mutant containing a duplication of the left end of the genome at the right end

A mutant (dp 201) of human adenovirus type 2 has been isolated that has the left 3% (1110 bp) of the genome duplicated at the right terminus. The structure of the mutant genome was studied by restriction endonuclease analysis and by direct DNA sequence analysis. The duplication has resulted in a deletion of 10 bp of the right inverted terminal repeat (ITR) at the junction of right and left end sequences. This internal ITR is not active in initiation or termination of DNA synthesis. Two subclones of dp 201 that bear a deletion between map positions 2.1 and 6.8 encompassing early gene blocks E1a and E1b were also isolated. One of these isolates (dl 201.1) retains the left end duplication and the other isolate (dl 201.2) lacks the left end duplication and is an apparent revertant of dl 201.1. The original mutant dp 201 also reverts to a wild type sequence at a low rate. Since 10 base pairs of the right ITR are deleted in the mutant, reversion must involve a repair mechanism using one of the two complete left end ITRs in the mutant genome. The mechanisms by which this reversion may occur are discussed.

Inhibition of adenovirus DNA synthesis in vitro by sera from patients with systemic lupus erythematosus

Sera containing antinuclear antibodies from patients with systemic lupus erythematosus (SLE) and related disorders were tested for their effect on the synthesis of adenovirus (Ad) DNA in an in vitro replication system. After being heated at 60 degrees C for 1 h, some sera from patients with SLE inhibited Ad DNA synthesis by 60 to 100%. Antibodies to double-stranded DNA were present in 15 of the 16 inhibitory sera, and inhibitory activity copurified with anti-double-stranded DNA in the immunoglobulin G fraction. These SLE sera did not inhibit the DNA polymerases alpha, beta, gamma and had no antibody to the 72,000-dalton DNA-binding protein necessary for Ad DNA synthesis. The presence of antibodies to single-stranded DNA and a variety of saline-extractable antigens (Sm, Ha, nRNP, and rRNP) did not correlate with SLE serum inhibitory activity. Methods previously developed for studying the individual steps in Ad DNA replication were used to determine the site of inhibition by the SLE sera that contained antibody to double-stranded DNA. Concentrations of the SLE inhibitor that decreased the elongation of Ad DNA by greater than 85% had no effect on either the initiation of Ad DNA synthesis or the polymerization of the first 26 deoxyribonucleotides.

Conserved sequences at the origin of adenovirus DNA replication

The origin of adenovirus DNA replication lies within an inverted sequence repetition at either end of the linear, double-stranded viral DNA. Initiation of DNA replication is primed by a deoxynucleoside that is covalently linked to a protein, which remains bound to the newly synthesized DNA. We demonstrate that virion-derived DNA-protein complexes from five human adenovirus serological subgroups (A to E) can act as a template for both the initiation and the elongation of DNA replication in vitro, using nuclear extracts from adenovirus type 2 (Ad2)-infected HeLa cells. The heterologous template DNA-protein complexes were not as active as the homologous Ad2 DNA, most probably due to inefficient initiation by Ad2 replication factors. In an attempt to identify common features which may permit this replication, we have also sequenced the inverted terminal repeated DNA from human adenovirus serotypes Ad4 (group E), Ad9 and Ad10 (group D), and Ad31 (group A), and we have compared these to previously determined sequences from Ad2 and Ad5 (group C), Ad7 (group B), and Ad12 and Ad18 (group A) DNA. In all cases, the sequence around the origin of DNA replication can be divided into two structural domains: a proximal A . T-rich region which is partially conserved among these serotypes, and a distal G . C-rich region which is less well conserved. The G . C-rich region contains sequences similar to sequences present in papovavirus replication origins. The two domains may reflect a dual mechanism for initiation of DNA replication: adenovirus-specific protein priming of replication, and subsequent utilization of this primer by host replication factors for completion of DNA synthesis.

Physical mapping of the genome and sequence analysis at the inverted terminal repetition of adenovirus type 4 DNA

The genome of adenovirus type 4 (Ad4), the unique member of Ad group E, has been mapped with nine restriction endonucleases. Comparison of the occurrence of restriction endonuclease cleavage sites on Ad2, Ad7, Ad12 and Ad4 indicates that there is very little homology between these serotypes. Sequence analysis at the ITR of Ad4 showed that the "CAT" box which is present in all the ITRs of Ad's so far sequenced is absent in Ad4. The length of 116 bp for the ITR of Ad4 is also different from that of other Ad subgroups.

Physical mapping of human adenovirus type 7 DNA using a simple and sensitive method of terminal labeling

The tyrosine-containing peptide covalently attached to each 5'-terminus of adenovirus type 7 (Ad 7; Greider) DNA was labeled with 125I. The 5'-labeled DNA was subjected to digestion with several restriction endonucleases and the size of the labeled terminal fragments was determined. Partial hydrolysis by these endonucleases generated a series of labeled fragments which were fused to the terminal fragments and could, therefore, be detected by autoradiography. From the sizes of the partial products the location of the cleavage sites of the enzymes on Ad7 DNA could be determined. The subgenomic DNA extracted from incomplete particles by protease treatment could also be labeled with 125I, since it was found to contain the tyrosine-containing peptide covalently attached to the preferentially packaged left end of the genome.

Formation of a covalent complex between the 80,000-dalton adenovirus terminal protein and 5'-dCMP in vitro

An in vitro adenovirus DNA replication system catalyzed the formation of a covalent complex between an 80,000-dalton protein and 5'-dCMP in the presence of [alpha-32P-dCTP, MgCl2, ATP, and adenovirus (Ad) DNA with a protein covalently bound to the 5' end of each strand (Ad DNA-prot). The requirement for Ad DNA-prot in this reaction was similar to that for in vitro DNA replication. When dATP, dTTP, and the 2',3'-dideoxynucleoside triphosphate (ddNTP) ddGTP were included in the reaction mixture, an elongated complex was detected, which consisted of an 80,000-dalton protein bound to a 26-base oligonucleotide. Formation of the elongated product, but not of the protein-dCMP complex, was inhibited by ddATP, ddCTP, or ddTTP. The requirements for formation of the protein-dCMP complex, the nature of the linkage between protein and dCMP, the size of the protein, and the existence of elongated forms indicated that the protein associated with the complex was identical to the 80,000-dalton Ad terminal protein found on replicating DNA molecules as described by Challberg et al. [Challberg, M. D., Desiderio, S. V. & Kelly, T. J., Jr. (1980) Proc. Natl. Acad. Sci. USA 77, 5105-5109].

Terminal proteins and short inverted terminal repeats of the small Bacillus bacteriophage genomes

The genome of Bacillus phage phi 29 contains covalently linked protein at both ends. These DNA terminal proteins are essential for phi 29 DNA replication. We have isolated phi 29 terminal protein from each end separately and compared their two-dimensional peptide maps. Our results showed the two proteins to be identical. The DNAs of four phages examined (phi 15, Nf, M2Y, and GA-1) also contain protein at both ends of the DNA molecules. The chymotryptic peptide maps of these DNA terminal proteins have been compared with the map of the phi 29 terminal protein. Despite the similarities in molecular size, peptide maps of the terminal proteins show clear differences among the unrelated phages. These results are consistent with the idea that the terminal proteins are encoded by viral DNA rather than by the host chromosome. We have also determined the nucleotide sequences of the termini of four phage DNAs and compared them with the sequence of phi 29 DNA. The sequence data indicate that all of these phages DNA contain short inverted terminal repeats: 5'A-A-A-G-T-A for phi 29 and phi 15, 5' A-A-A-G-T-A-A-G for Nf and M2Y, and 5' A-A-A-T-A-G-A for GA-1.

Nucleotide sequences at the termini of phi 29 DNA

The nucleotide sequences of the first 422 base pairs from the left-hand end and the first 274 base pairs from the right-hand end of phi 29 DNA were determined by using the chemical degradation method of Maxam and Gilbert. The data indicate that phi 29 DNA has inverted terminal repetitions that are six base pairs long 5' (-A-A-A-G-T-A-). No perfectly self-complementary sequence exists within the terminal regions of phi 29 DNA, suggesting that DNA replication via a self-priming mechanism is improbable. The putative early promoter sequences were found in both ends of the phi 29 DNA. The results of the sequence determination are discussed in relation ship to models proposed for the mechanism of replication of linear DNA molecules.

Nucleotide sequence at the termini of the DNA of Bacillus subtilis phage phi 29

Phage phi 29 DNA cannot be phosphorylated with polynucleotide kinase and [gamma-32P]ATP because of the presence of a viral protein covalently linked to the 5' termini. The 5' ends can, however, be made susceptible to phosphorylation by treatment with alkali and alkaline phosphatase. Restriction fragments Hpa II C and Hpa II F, corresponding to the right and left ends of phi 29 DNA, respectively, were labeled at the 5' ends with polynucleotide kinase and [gamma-32P]ATP or at the 3' ends with terminal transferase and [alpha-32P]ATP or [alpha-32P]cordycepin 5'-triphosphate. After a secondary cleavage of the labeled fragments, the sequence of the first 150-180 nucleotides at the termini of phi 29 DNA was determined by the method of Maxam and Gilbert. The ends of phi 29 DNA are flush, and a six-nucleotides-long inverted terminal repetition was found. The functional implications of the sequences determined are discussed.

Adenovirus DNA replication in vitro: a protein linked to the 5' end of nascent DNA strands

Soluble nuclear extracts prepared from adenovirus-infected HeLa cells supported adenovirus DNA replication with exogenous DNA-protein complex as template, but protease-treated, phenol-extracted DNA was less active. Replication was enhanced when creatine phosphate and creatine phosphokinase were included in the reaction mixture, rendering the reaction independent of exogenous ATP. Genomic-length, newly synthesized DNA strands were first observed 30 min after initiation of replication and continued to increase in amount for at least 4 h. Thus, the rate of replication is consistent with previous estimates of the rate of replication in vivo. Nascent DNA strands bound to benzoylated, naphthoylated DEAE-cellulose due to their association with protein. The 5' termini of nascent DNA strands were resistant to the 5'- to 3'-specific T7 exonuclease, and the 3' termini of nascent strands were sensitive to the 3'- to 5'-specific exonuclease III. These results suggest that a protein becomes covalently linked to the 5' termini of nascent DNA strands replicated in vitro. Nuclear extracts prepared from adenovirus type 2-infected cells also supported replication of DNA-protein complex prepared from the unrelated type 7 adenovirus. The limited sequence homology between these two viruses at the origin of replication further defines recognition sequences at the origin. These results are discussed in terms of a model for adenovirus DNA replication in which the terminal protein and sequences within the inverted terminal repetition are involved in the formation of an initiation complex that is able to prime DNA replication.

Comparison of nucleotide sequences of the early E1a regions for subgroups A, B and C of human adenoviruses

The early E1a regions (map position (0--4.5%) of highly oncogenic (subgroup A) adenovirus serotype 12 (Ad12), weakly oncogenic (subgroup B) adenovirus serotype 7 (Ad7) and non-oncogenic (subgroup C) adenovirus serotype 5 (Ad5) can convert cells in vitro into an immortal cell line. A comparison of the nucleotide sequences for the E1a regions of Ad12 (Sugisaki et al., 1980), Ad7 (Dijkema et al., 1980), and Ad5 (Van Ormondt et al., 1978) DNA is presented. The overall homology is about 50%, but certain segments of the E1a regions exhibit higher than average homology, for both coding and noncoding sequences. The latter may specify the initiation of DNA replication, DNA encapsidation and regulation of expression. The predicted polypeptides encoded by the E1a regions of the three serotypes exhibit a large degree of homology.

The nucleotide sequence of the transforming early region E1 of adenovirus type 5 DNA

The sequence of the leftmost 11.3% of the non-oncogenic human adenovirus type 5 (Ad5) DNA has been determined. This segment contains the entire early region E1 of the Ad5 genome which has been shown to be involved in in vitro transformation of non-permissive rodent cells (Van der Eb et al., 1980). From the DNA sequence, and from the mRNA sequence data obtained by Perricaudet et al, (1979, 1980) for the E1 mRNAs from the closely related adenovirus type 2 (Ad2), it is possible to predict the primary structure of the polypeptides encoded by this region. The function of these proteins in cell transformation is discussed. From the positions of mapped restriction endonuclease sites and termini of RNA segments in the nucleotide sequence the length of the Ad5 DNA is estimated to be 36.6 kb.

Structure and gene organization in the transformed Hind III-G fragment of Ad12

The nucleotide sequence of the transforming Hind III-G fragment of Ad12 DNA which encompasses the left 6.8% of the genome has been determined. The fragment was 2320 nucleotides long, and contained a GC cluster at positions 126-155 and a region extremely rich in AT at positions 1098-1142 (number from the leftmost end). Possible coding regions for the two transforming gene products were assigned. The predicted coding region for T antigen g is positions 502-1069 and positions 1144-1373, which are joined by splicing (266 amino acid residues, 30 kd), and that for T antigen f is positions 1845-2126 (94 amino acid residues, 10 kd). The sequence of the Hind III-G fragment was compared with that of the transforming DNA fragment of Ad5 which encompasses the left 8.0% of the genome (2809 nucleotides). There are several discrete regions with significant sequence homology. The comparison suggests that the regions in the left two thirds of the Ad5 and Ad12 transforming DNA fragments (map units 0-4.7% in Ad5 and 0-4.4% in Ad12) bear some resemblance in their gene organizations, and code for proteins containing structurally homologous regions.

Comparative sequence analysis of the inverted terminal repetitions from different adenoviruses

The comparative nucleotide sequences of the region of inverted terminal repetition from a representative member of group C (nononcogenic), group B (weakly oncogenic), and group A (highly oncogenic) adenoviruses are analyzed. Our data show that (i) the length of this unique region increases with the oncogenicity of the serotype, (ii) a unique homologous region--14 nucleotides long--is present exactly at the same distance from the terminus, and (iii) a hexanucleotide sequence, T-G-A-C-G-T, is present at the site where the terminal repetition diverges.

The nucleotide sequence of the transforming BglII-H fragment of adenovirus type 7 DNA

The nucleotide sequence of the leftmost BglII-H fragment (0--4.5%) of weakly oncogenic human adenovirus serotype 7 (Ad7) has been determined (1568 base pairs). This is the shortest Ad7 DNA fragment reported to transform primary rat cells into an immortal cell line (Dijkema et al., 1979). The l-strand of BhlII-H was found to contain the complete information for a polypeptide of at most 28 051 daltons, followed by the putative promoter site of the next gene. Comparison of the determined Ad7 sequence with that of the corresponding region of non-oncogenic Ad5 (Van Ormondt et al., 1978; Maat and Van Ormondt, 1979) showed that the over-all organization of the two DNAs is quite similar, but that the sequences, except in regions of suspected strategic importance, diverge considerably.

The nucleotide sequence of the right-hand terminal SmaI-K fragment of adenovirus type 2 DNA

The primary structure of the SmaI-K fragment of adenovirus type 2 (Ad2) DNA has been determined. This region includes one of the origins of DNA replication (Winnacker, 1978; Sussenbach and Kuijk, 1978). A leader sequence for an early mRNA in region 4 (Berk and Sharp, 1977; 1978) has also been mapped in this region. The comparison of the primary structure of this region in Ad2 DNA with the corresponding region in Ad5 DNA shows a remarkable homology which may be significant in view of the fact that Ad2 and Ad5 DNAs can interchangeably function in the in vitro replication system of Challberg and Kelly (1979).

The inverted terminal repetition of the DNA of weakly oncogenic adenovirus type 7

By use of the chemical modification technique of Maxam and Gilbert (1977), the first 180 base pairs at both termini of the human adenovirus 7 genome have been determined. The results show that adenovirus 7 DNA contains a perfect inverted terminal repetition of 136 base pairs.